Digital processing device with disparate magnetoelectronic gates

ABSTRACT

Magnetic spin devices can be used as a memory element or logic gate. When connected in a circuit configuration, different spin devices can be written to in any number of different ways, such as with different device coercivities, different sets of write lines, different signal amplitudes, different read/write line orientations, etc.

RELATED APPLICATION DATA

The present invention claims priority to and is a continuation of Ser. No. 10/853,792 filed May 24, 2004 now U.S. Pat. No. 6,958,930, which is a continuation of application Ser. No. 10/100,210 filed Mar. 18, 2002 entitled “Magnetoelectronic Memory Element With Inductively Coupled Write Wires” now U.S. Pat. No. 6,741,494. Application Ser. No. 10/100,210 is a continuation of an application Ser. No. 09/532,706 filed Mar. 22, 2000 titled “Magnetoelectronic Memory Element With Isolation Element” (now U.S. Pat. No. 6,388,916). The latter application Ser. No. 09/532,076 is in turn a divisional application of Ser. No. 08/806,028 filed Feb. 24, 1997 entitled “Hybrid Hall Effect Memory Device & Method of Operation,” now U.S. Pat. No. 6,064,083. Ser. No. 08/806,028 is a continuation-in-part of Ser. No. 08/643,805, filed May 6, 1996 titled “Hybrid Hall Effect Device and Method of Operation,” (now U.S. Pat. No. 5,652,445), which in turn is a continuation-in-part of an application Ser. No. 08/493,815, filed Jun. 22, 1995 titled “Magnetic Spin Transistor Hybrid Circuit Element,” (now U.S. Pat. No. 5,565,695); and said Ser. No. 08/806,028 is also a continuation-in-part of an application Ser. No. 08/425,884, filed Apr. 21, 1995 titled “Magnetic Spin Transistor, Logic Gate & Method of Operation,” (now U.S. Pat. No. 5,629,549); and an application Ser. No. 08/643,804 filed May 6, 1996 titled “Magnetic Spin Injected Field Effect Transistor and Method of Operation,” (now U.S. Pat. No. 5,654,566).

The above applications and materials are expressly incorporated by reference herein.

FIELD OF THE INVENTION

The invention relates generally to ferromagnetic electronic devices. In particular, the invention relates to different types of Magnetoelectronic devices used for memory, logic, and other functional applications.

BACKGROUND OF THE INVENTION

Typical contemporary digital electronic circuits are based primarily on transistor devices fabricated from semiconductor materials. In fact, the development of microfabricated bipolar and field effect transistors led directly to the modern development of digital electronic circuits and microprocessors [see texts by Horowitz and Hill, “The Art of Electronics”; D. V. Bugg, “Circuits, Amplifiers and Gates”]. Digital electronics refers to circuits in which there are only two states possible at any point. Typically these states are set by gate circuits comprised of one or more interconnected microfabricated semiconductor transistors that can be in one of two stable states: saturation or nonconducting. Because the gates have characteristically high impedance, these semiconductor transistors (and circuits) use electrodynamic input and output in the form of digital voltage pulses. These semiconductor transistors and circuits are directly electrically connected together by some conductive material. The voltage states corresponding to saturation and nonconducting are HIGH and LOW, which represent, respectively, the TRUE and FALSE states of Boolean logic. These states also correspond to bits of information, typically HIGH represents a “1” and LOW a “0.”

The class of tasks in which the output or outputs are predetermined functions of the input or inputs is called “combinational” tasks. These tasks can be performed by semiconductor transistor gates which perform the operations of Boolean algebra applied to two-state systems. Combinational logic is basic to digital electronics. The three most popular semiconductor transistor logic families presently in use are Transistor-Transistor logic (TTL), Metal Oxide Semiconductor (MOS) logic and Complimentary MOS (CMOS) logic.

A disadvantage of such semiconductor transistors is the fact that their size and packing density is limited by the inherent physics of their operation, including thermal restrictions and density of charge carriers. Moreover, to implement the logic of even a simple single logic gate (such as an AND gate for example) in semiconductor digital electronics usually requires a circuit composed of several transistors [and possibly resistors and diodes] which takes up further space. Finally, to make semiconductor devices that are non-volatile—i.e., to retain a particular logical state—typically requires complex device logic support structures and/or operational characteristics.

The above considerations, and others well known in the art, restrict the packing density of semiconductor devices. Recently, a new magnetic spin transistor has been developed which can perform substantially all of the operations associated with semiconductor transistors. This new transistor, including its structure and operation, is described in detail in articles authored by me and appearing in IEEE Potentials 14, 26 (1995), IEEE Spectrum Magazine 31 no. 5, pp. 47–54 (May 1994), Science, 260 pp. 320–323 (April 1993), all of which are hereby incorporated by reference.

The structure, however, of this new magnetic spin transistor has prevented it use as a logic gate for performing digital combinational tasks. To date in fact, such magnetic spin transistors have been limited to such environments as memory elements, or magnetic field sensors.

Moreover, a major problem to date has been the fact that there has been no feasible or practical way to interconnect one or more spin transistors together. This is because, unlike semiconductor transistors, spin transistors are low impedance, current biased devices, which cannot be directly electrically interconnected from one to another by using electrodynamic coupling and the transmission of voltage pulses.

Finally, another problem with previously known magnetic spin transistors is the fact the output current of such devices has not be large enough to accomplish current gain. Lack of current gain is another reason why contemporary magnetic spin transistors cannot be successfully interconnected together to form digital processing circuits, because the output of one device must be capable of setting the state of another device, a condition that can be stated as requiring that device fanout must be greater than one.

SUMMARY OF THE INVENTION

An object of the present invention therefore is to provide an improved magnetic spin transistor that can be used as a logic gate for performing digital combinational tasks, as well as in all other environments (including memory applications).

Another object of the present invention is to provide a new structure and method for interconnecting one or more spin transistors together.

A related object of the present invention is to provide a new structure for a magnetic spin transistor processing circuit having logically interconnected elements.

A further object of the present invention is to provide an improved magnetic spin transistor which has current gain, and therefore is capable of setting the state of another spin transistor device.

According to the present invention, an improved magnetic spin transistor (having two ferromagnetic layers and a paramagnetic layer) is fabricated with ferromagnetic and nonmagnetic materials and may be fabricated entirely from metals. This magnetic spin transistor is provided having a conductive write layer for carrying a write electric current and inductively coupling a write magnetic field associated with this write current to the second (collector) ferromagnetic layer of the spin transistor. The first (emitter) and second (collector) ferromagnetic layers of this new transistor are both fabricated to be magnetically anisotropic so as to permit the collector to have two stable magnetization states (up and down). An external current generator can change the magnetization state of the collector by inductively coupling a magnetic field to the collector.

Even if power is removed from the above device, the second ferromagnetic layer magnetization orientation is retained in its set state, thus causing the spin transistor to behave as a non-volatile memory element, because the two states of the magnetization orientation of said second ferromagnetic layer can correspond to data values stored in said memory element. An array of spin transistors can be coupled together in an array to form a spin transistor memory array. The present magnetic spin transistor therefore will find application as the basic storage element in integrated arrays of nonvolatile random access memories (NRAM), and may replace DRAM and direct access memory (such as magnetic disk drives) in many applications.

Further according to the present invention, a spin transistor logic gate can be fabricated using the above improved spin transistor. This gate can implement any desired combinational task (function) relating one or more inputs to said spin transistor to an output of the spin transistor. Depending on the particular function to be implemented, the state of the gate (the initial magnetization state of the collector) is first set using a magnetic field generated by a current pulse transmitted through a write wire inductively coupled to the gate (the ferromagnetic collector of the spin transistor). This same wire also inductively couples a magnetic field generated by the combined current of one or more input data signals to the spin transistor. Again, depending on the particular function to be implemented the ferromagnetic collector magnetization can be configured (in combination with the current level associated with the input data signals and the coupling of the wire carrying this current with the ferromagnetic collector) to change or remain the same depending on the particular combination of input data signals. In other words, the ferromagnetic collector magnetization may be read out as an output binary “1” or “0” corresponding to some Boolean logical combination task depending on the data input signals. In any specific embodiment, therefore, the present invention can be configured to implement the function of any of the following gates: an OR gate, a NOR gate, a NOT gate, a NAND gate, an AND gate, or more generally any logic gate implementing a logical combinational task relating one or of inputs/outputs.

The present magnetic spin transistor logic gate invention is a substantial improvement over prior semiconductor gates using semiconductor transistors. Among other things, a unique dynamically programmable logic gate is provided by the present invention. This is because the initial magnetization of the ferromagnetic collector, the amplitude of the input signal currents on the write wire, and/or the coupling of the input signal current to the spin transistor can all be controlled and changed dynamically to configure the spin transistor logic gate to implement a different logical function. Furthermore, whereas a single logic gate in semiconductor digital electronics is itself a circuit composed of several transistors [and possibly resistors and diodes], the spin transistor logic gate is composed of a single spin transistor element.

In accordance with another embodiment, the present magnetic spin transistor invention can also be constructed so that the output current is larger than the write current, thus operating [albeit in a nonconventional sense] with current gain. Unlike prior spin transistor embodiments, the parasitic impedance, transimpedance and load impedance (which impedances are explained more fully below) of the present invention can be designed and implemented so as to permit any form of spin transistor output (i.e., current or voltage) having any desired offset.

According to another aspect of the present invention, a magnetic spin transistor can now be operatively connected to another spin transistor device by inductively coupling the output current pulse of one spin transistor to the input of another transistor. Using this method, several gates can also be linked together by coupling the output of one gate to the write line of another gate.

In this way, an arrangement of gates can be assembled to operate as a half adder, which is the basic functional unit of digital processing; half adders can be joined together to perform all the usual mathematic functions. Combined with the memory functions of spin transistors, the additional capability of amplifying current and performing combinational tasks means that entire microprocessors can be fabricated entirely from spin transistor components, using no semiconductor devices.

The advantages of magnetic spin transistors over semiconductor transistors are significant. First, magnetic spin transistors can be fabricated entirely from metals, and thus are not susceptible to the thermal restrictions on packing density, nor on the intrinsic restriction imposed by the density of charge carriers, that affect semiconductor devices. For these reasons, spin transistors and logic gates made from such transistors may be fabricated on a scale much smaller than semiconductor processors, and higher densities may be achieved.

It is further expected that such spin transistors will draw less power than their semiconductor equivalents, and have a further advantage that they will not need require synchronization to a clock. Finally, spin transistors and circuits incorporating such transistors have the inherent advantage of non-volatility because the magnetization state or result of the logical step is automatically stored in the gate for indefinite time [drawing zero quiescent power] and is available for readout whenever it is needed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view of a trilayer structure illustrating the basic structure and operation of a typical magnetic spin transistor.

FIG. 2 is a cross-sectional view of the trilayer structure in FIG. 1 showing an embodiment of the present invention wherein circuit elements are used to offset the output current or voltage.

FIG. 3 is a cross-sectional view of the trilayer structure of the present basic improved magnetic spin transistor invention which is usable for any number of operating environments.

FIG. 3A is a perspective view of same trilayer structure of the present basic improved magnetic spin transistor invention, showing the paramagnetic base, ferromagnetic emitter, ferromagnetic collector and connections thereto;

FIG. 3B is a perspective view of a write wire inductively coupled to the present improved spin transistor/spin transistor gate.

FIG. 3C is a perspective view of two write wires inductively coupled to one spin transistor element in an array of spin transistor elements.

FIGS. 4A, 4B and 4C are schematic views of the present improved spin transistor operating as an OR gate.

FIGS. 5A, 5B and 5C are schematic views of the present improved spin transistor operating as an AND gate.

FIGS. 6A and 6B are schematic views of the present improved spin transistor operating as an NOT gate.

FIGS. 7A, 7B and 7C are schematic views of the present improved spin transistor operating as an NOR gate.

FIGS. 8A, 8B and 8C are schematic views of the present improved spin transistor operating as an NAND gate.

FIGS. 9A, 9B and 9C are perspective views of various fabrication geometries used in the present invention for write wires and output leads which allow the present device to be connected to other spin transistor devices, and to operate with current gain.

FIG. 10 is a schematic view of one embodiment of the present invention wherein a system of spin transistor gates can operate to perform the task of a half adder.

DETAILED DESCRIPTION OF THE INVENTION

Before explaining the details of the new magnetic spin transistor, or its implementation as a logic gate or in other environments, a brief review of the operating principles and device characteristics of the spin transistor will be provided for purposes of putting the present invention in context. While specific details of the physics of these devices is not important for purposes of the present invention, a more detailed discussion can be found in the aforementioned Science and IEEE Spectrum articles.

Most embodiments rely on a trilayer structure drawn schematically in cross-section in FIG. 1. Ferromagnetic emitter 12 and ferromagnetic collector 14 are thin films of iron, cobalt or permalloy Ni_(x)Fe_(1−x), although any electrically conductive, single domain ferromagnetic layers may be used. Paramagnetic base 16 is gold, copper, or aluminum, but any conductive paramagnetic material, i.e, any material having electron levels that are not significantly affected by the electron spin so that there is little splitting between the spin subbands is acceptable. The equilibrium energy levels for typical paramagnetic materials are substantially the same for the two electronic spins. Alternatively, a non-paramagnetic material that can be made paramagnetic through known means is also acceptable.

It will be understood by skilled artisans that the terms “ferromagnetic emitter,” “paramagnetic base” and “ferromagnetic collector” serve as short hand descriptive aids in this field for understanding the present invention. In same ways, these terms suggest a natural analogy with semiconductor devices. While such analogies may be helpful pedagogical notions, no limitations or relationships typically associated with or between such structures in the physics of semiconductor transistors should be presumed to apply to the corresponding ferromagnetic and paramagnetic regions of the present invention. A full understanding of the limitations and relationships of such regions in the present invention is provided herein, in the above articles, and in other prior art materials discussing magnetic spin transistors.

Each of the three films typically has a thickness greater than an electron mean free path, typically tens to hundreds of nanometers. The thickness of the paramagnetic base 16 is preferably less than the spin diffusion length δ_(s) typically of order 1 micron in polycrystalline metal films such as gold, copper, silver, aluminum or niobium, and defined to be the length l in the paramagnetic base over which a induced nonequilibrium magnetization M_diffuses while the amplitude diminishes to 1/e of the initial value, M_=M_(—0) e^(−1/) ^(δ) .

In general the orientation of the magnetizations of the ferromagnetic emitter 12 and ferromagnetic collector 14, M_(E) and M_(C), can lie in any direction. It is common to use ferromagnetic materials with in-plane anisotropies so that M_(E) and M_(C) are restricted to lie in the plane of the films, in which case the device has a continuum of states with each state corresponding to the projection of the magnetization of M_(C) on M_(E). For digital applications, the device is preferably fabricated using ferromagnetic films with parallel anisotropy axes in the film plane. The ferromagnetic emitter 12 is fabricated from a material with a large coercivity [and/or a large exchange bias or pinning anisotropy] and the ferromagnetic collector 14 is fabricated from a material with a smaller coercivity. Thus, M_(E) is initially polled in the up orientation, denoted in FIG. 1 by the up arrow within the ferromagnetic emitter 12, and it remains in this state. Under these conditions a spin transistor acts as a two state device, corresponding to the two stable states of M_(C), up and down (parallel or antiparallel to M_(E)). These two equally likely states are represented in FIG. 1 by the dashed arrows, up and down, within the ferromagnetic collector 14. For the chosen convention of M_(E) up, the two device states are determined by the state of M_(C) and are hereafter labeled as “up” and “down.” Those skilled in the art will appreciate that M_(E) could be chosen down and a two state device would exist with opposite output polarity; moreover, an equivalent notation, sometimes used in the literature, is M_(E) and M_(C) parallel or antiparallel.

A conventional spin transistor such as shown in FIG. 1 is a three terminal, current biased, low impedance device with a bipolar voltage or current output that depends on the state of the device [i.e. that depends on the projection of M_(C) on M_(E)]. An electrical source 18 pumps positive bias current I_(E) from the ferromagnetic ermitter 12 to the paramagnetic base 16 and creates a nonequilibrium population of spin polarized electrons, equivalently a nonequilibrium magnetization M_in the paramagnetic base. In the simplest analysis, much of the bias current returns to the source by the path through node II. The nonequilibrium magnetization in the paramagnetic base generates an electric field at the paramagnetic base—ferromagnetic collector interface, and the sign of the field depends on the magnetization orientation of the ferromagnetic collector M_(C) with respect to the orientation of the polarized electrons, and therefore with respect to M_(E). When M_(E) and M_(C) are parallel the electric field generated at the interface pushes electric current from the paramagnetic base into the ferromagnetic collector, and when they are antiparallel the field pulls electric current from the ferromagnetic collector into the paramagnetic base.

Since current in the circuit of FIG. 1 is conserved, the interfacial electric field can be considered as a “battery” that generates a circulating current in the ferromagnetic collector arm of the circuit, either clockwise or counter-clockwise. Quantitatively, the interfacial electric field that is generated by the nonequilibrium population of polarized spins can be described by a transimpedance R_(S). The spin-coupled voltage V_(S) developed across the interface is linearly proportional to bias current, R_(S)=|V_(S)|/I_(E), where R_(S) is defined as positive and V_(S) is bipolar. The magnitude of R_(S) is inversely proportional to the volume of the paramagnetic conducting material (the paramagnetic base) between the ferromagnetic emitter and ferromagnetic collector, and can be of the order of ohms for devices fabricated with a spatial scale on the order of a micron.

In FIG. 1, the ferromagnetic collector arm of the circuit contains an arbitrary (selectable) load resistance 20, also called R_(L). The response of the spin transistor to several loading configurations can now be discussed.

In the first extreme case let R_(L)

0 so that the ferromagnetic collector arm of the circuit behaves as a short circuit ammeter. Then current flow in the ferromagnetic collector arm will be clockwise and positive, from node I through R_(L) to node to II, when M_(C) is up [M_(E) and M_(C) parallel], and counter-clockwise and negative (current will flow from II to I) when M_(C) is down [M_(E) and M_(C) antiparallel].

In the second extreme case let R_(L)

∞ so that the ferromagnetic collector arm of the circuit represents an open circuit voltmeter. Then the voltage V_(I) at node I is positive with respect to the voltage at the paramagnetic base, V_(I)>V_(II), when M_(C) is up, and V_(I) is negative with respect to the paramagnetic base when M_(C) is down.

First Embodiment—Magnetic Spin Transistor with Adjustable Output Offset

A first embodiment of my improved spin transistor design is shown electrically in FIG. 2. This embodiment shows changes that I have discovered more realistically model spin transistor devices as real circuit elements. First, separate grounds have been drawn for the electrical source 18, paramagnetic base 16 and ferromagnetic collector 14 to represent the fact that these components may be grounded at spatially remote parts of a circuit. Second, a parasitic resistance 22, also denoted R_(B) has been explicitly included between the paramagnetic base and ground. This represents the fact that there is always some finite resistance from the paramagnetic base to ground including, for example, the intrinsic resistance of the paramagnetic conducting material comprising the paramagnetic base itself. In typical prior art spin transistor embodiments, R_(B) is considered to be negligibly small or exceedingly large, and in these embodiments the output current or voltage is limited to be symmetrically bipolar.

In the present invention, R_(B) is adjusted relative to the transimpedance R_(S) to permit the output of a spin transistor to be offset by an desired amount to effectuate anything from a full bipolar to a unipolar output for any known load resistance R_(L). The adjustment of R_(B) relative to the transimpedance R_(S) can be accomplished by altering the geometry of the paramagnetic base 16 relative to the ferromagnetic emitter 12 and ferromagnetic collector regions 14, such as by varying the thickness and transverse dimensions of the paramagnetic conducting material outside the region between ferromagnetic emitter and ferromagnetic collector, or introducing a low transmission barrier at either interface or at any boundary to the paramagnetic base region (the region between ferromagnetic emitter and ferromagnetic collector), or by using different materials for the paramagnetic base such as niobium. In this manner, R_(B) can be made to be on the same order, or larger than the transimpedance R_(S).

Unlike prior spin transistor embodiments that only accommodate the extreme cases of R_(L)=0 or ∞, the present invention, by adjusting the above parameters, can generate a useful output for any value of R_(L). The response of the spin transistor of the present invention in FIG. 2 to a general loading configuration R_(L) and general value of R_(B) can now also be discussed.

The net current flow in the ferromagnetic collector is the superposition of the circulating current driven by V_(S) and the background, ohmic current flow resulting from the parallel combination of R_(L) and R_(S). It is possible, as explained above, to vary the value and ratio of R_(L), R_(S) and R_(B) so that the bipolar output is offset upwards. For example, using values R_(L)=R_(B)=R_(S) the output is offset up by an amount R_(S). In this case, the current output through R_(L) is positive when M_(C) is up [M_(E) and M_(C) parallel], and zero when M_(C) is down [M_(E) and M_(C) antiparallel]. This specific output offset is used during the following discussion of digital operation.

Second Embodiment—Magnetic Spin Transistor with Write Wire

The operation of an improved spin transistor invention 10 is shown in FIG. 3. In this figure, while the spin transistor also includes adjustable offset, the parasitic paramagnetic base resistance R_(B) has not been included in the drawing and any load resistance has been replaced by a meter [detector] 32 that displays the output current or voltage of the ferromagnetic collector arm of the circuit and has characteristic impedance R_(L). A bias current can be applied in the form of digital pulses 40; this can also be considered as a read current I_(R). The orientation M_(C) of the magnetization of the ferromagnetic collector can be set to a stable state by using localized pulses of magnetic field. An integrated wire fabricated in close proximity to the ferromagnetic collector film 14 is called a write wire 36. A pulse of positive electric current 34, called a write pulse, transmitted down the write wire generates a magnetic field 38 close to the write wire. The write wire is situated so that a positive current generates a field 38 at the ferromagnetic collector that is positive (up in FIG. 3) and the magnetization orientation of M_(C) will be set upwards in response to this field if it is of sufficient magnitude. When no current is transmitted in the write wire there is no magnetic field and the magnetization orientation M_(C) retains its initial orientation because of hysteresis. If a sufficiently large negative current pulse is transmitted down the write wire, the associated magnetic field pulse will be negative, pointing downwards at the ferromagnetic collector, and M_(C) will be set to point down. While element 36 in FIG. 3 has been described as a “wire” it will be understood by persons skilled in the art that any number of well-known structures capable of carrying sufficient current (including for example a conductive film, or an interconnect line) to generate field 38 will be suitable in the present invention.

The structural configuration of the preferred embodiment of the improved spin transistor 300 shown with an integrated write wire is depicted in FIG. 3A. Ferromagnetic collector electrode 350 is a bilayer composed of ferromagnetic collector 352 and a thin overlayer 354 which serves to improve current flow and to protect the ferromagnetic collector against oxidation. The ferromagnetic collector electrode 350 may be rectangular in shape and may have transverse dimensions ranging from 0.1 to 50 microns. An electrically insulating material 384 coats a portion of the electrode. Write wire 382 (typically a metal film or other strongly conducting film) is fabricated over the insulator 384 so that it is electrically isolated from the ferromagnetic collector. It is understood that this spatial orientation can be inverted with the write wire underneath; in some geometries the spin transistor element can carry some of the current of the write pulse.

In FIG. 3A only a portion of the write wire 382 is shown; the wire extends to contact a bipolar current source at one end and a ground which is preferably a ground isolated from the magnetic transistor ground on the other end. Alternatively, write wire 382 can be connected to a single polarity source (such as a data input source that varies from 0 to some positive value). The vector magnetic field generated by current flow in the write wire 382 points in a circulating direction 386. For positive current the field at the position of the ferromagnetic collector 352 is positive along the z axis. The linear relationship between the magnitude of the field at the ferromagnetic collector 352 and the magnitude of the current in the write wire 382 is described by the inductive coupling parameter α. The field magnitude is directly proportional to the current magnitude, H=αI. As is well known in the art, a depends on the detailed geometry of the write wire 382, ferromagnetic collector electrode 350, and their spatial relationship. As such, it can be selected by a skilled designer to have any desired value. It is understood, for example, that α decreases as the thickness of the insulating layer 384 increases. In the preferred embodiments shown herein, α is chosen to have a value between 5 and 20 (in practical units where I is in amps and H in tesla).

The amplitude of the write pulse is determined so that the amplitude of the local magnetic field at the ferromagnetic collector is greater than (sufficient to overcome) the coercivity of the ferromagnetic collector and thus set the ferromagnetic collector to a different magnetization state. Again, it is well known in the art that the amplitude of the local magnetic field amplitude impressed on the ferromagnetic collector depends on the value of the inductive coupling parameter α, and the amplitude of the write current pulse. In the preferred embodiment, the write pulse has a current amplitude of 0.1 mA, and the amplitude of the local magnetic field is about 10 Oersted (α=8). The coercivity of the ferromagnetic emitter and ferromagnetic collector is selected to be 40 and 8 Oersteds respectively. The choice of specific current amplitude, field strength and coercivities to be used can be easily determined by one skilled in the art depending on the specific application desired.

In the detailed preferred embodiment shown in FIG. 3A, the ferromagnetic emitter 345 is typically a bilayer composed of a ferromagnetic conductor 346 made of iron, permalloy or cobalt (with a thickness 0.06 micron, a length of about 2 microns and a width of 1 micron) fabricated on a nonmagnetic conductor 347 which is used either to promote a magnetic anisotropy in the ferromagnetic conductor 346 (in which case the material could be nickel oxide with a thickness of 0.01 micron) or to promote isotropic current flow into the ferromagnetic emitter 345 (in which case the material would be gold, silver, aluminum or copper with a thickness of 0.08 micron). The ferromagnetic collector 250 is a bilayer composed of ferromagnetic conducting material 352 with a thickness 0.06 micron, a length of about 2 microns and a width of about 1 micron. Overlayer 354 is made of gold, silver, aluminum or copper, has a thickness of 0.08 micron, a length of 2 microns and a width of 1 micron. Write wire 382 is made of gold, silver, aluminum or copper, has a thickness of 0.1 micron and a width of 1 micron (the length extends out of the figure). Insulating layer 384 is made of polymide, aluminum oxide, silicon dioxide or silicon monoxide, has a thickness of 0.05 micron, a width of 1.2 microns and a length of 1.5 microns. The paramagnetic base 335 is made of gold, silver, copper or aluminum with a thickness of 0.1 micron, a width of 1 micron and a length of 2 microns.

As will be understood by those skilled in the art, the materials and dimensions described for the above structures are not critical within most reasonable limits. Typically, there are wide ranges of acceptable values for any particular application, and the final choice can made on the operating requirements of any chosen application for such magnetic spin transistors.

An alternative embodiment of the present invention, depicting the improved magnetic spin transistor as a memory element 300 in a memory array is shown in FIG. 3B. In such applications, an array of write wires is used. In FIG. 3B ferromagnetic collector electrode 350 of each element 300 of the array is fabricated in the vicinity of a pair of write wires, and the pair is unique for each element. Write wire 356, a segment of which is shown, is one member [I] of a column of [n] write wires, and write wire 358 is one member [j] of a row of [m] wires, with all n+m wires used to address each of the n*m elements of the [n] by [m] array. Each write wire 356 and 358 is connected to a bipolar current source at one end and ground at the other end, and the two wires are electrically isolated from each other by insulating layer 368 and from the ferromagnetic collector electrode by insulating layer 364.

The magnetic field at each ferromagnetic collector 352 of the array is the sum of the fields 362 and 360 generated from current in each wire 356 and 358. The current amplitude for the pulses simultaneously applied to each line and the inductive coupling parameter for each line are adjusted so that the net field H at each ferromagnetic collector 352 is slightly larger than the coercivity of the ferromagnetic collector. However, the field generated by either write line alone is less than the coercivity. Thus, appropriate current pulses of positive or negative polarity transmitted down the [I] and [j] write lines will orient the magnetization of the ferromagnetic collector of the element at the site with the address (i,j) to be positive or negative (up or down) but the magnetization orientation of the ferromagnetic collectors at other sites in row [I] or column [j] will not be affected.

Third Embodiment—Magnetic Spin Transistor Logic Gate

The following discussion explains the implementation of the magnetic spin transistor in digital operation as a logic gate. As an aid to understanding the present description, however, some simplifying conventions are useful.

Refer first to FIG. 3. When the ferromagnetic collector 14 has a coercivity H_(C,1) and the write wire 36 is fabricated with unit inductive coupling strength, the write pulse amplitude necessary to orient M_(C) is defined to be unitary. That is to say, when I_(W)=1 [arbitrary unit] in a write wire with coupling efficiency α=1, the generated magnetic field H at the position of the ferromagnetic collector is slightly [epsilon] larger than the coercivity, H_(C,1), H=H ₁>H_(C,1).

Secondly, for this embodiment, the geometry of the spin transistor is chosen so that R_(B) and R_(L) have values that offset the output upwards by the amount R_(S). As described above, the output of the device is then a positive current pulse (of amplitude 1) when M_(C) is up [M_(E) and M_(C) parallel], and zero current (or voltage) when M_(C) is down [M_(E) and M_(C) antiparallel].

Third, for this embodiment the amplitude of the bias current pulse [and R_(B) and R_(L) in typical circuits] is adjusted so that the output current amplitude I_(OUT) is identical with that of the unit write pulse, I_(OUT)=I_(W)=1.

With these parameters the spin transistor becomes a two-state digital logic gate which has memory and which can perform Boolean logic. The state with M_(C) up [M_(E) and M_(C) parallel] results in a HIGH, TRUE state with positive current (or voltage) output, and represents a binary value “1.” Positive write input pulses of unit amplitude are also HIGH, TRUE states with the binary value “1.” The state with M_(C) down [M_(E) and M_(C) antiparallel] results in a LOW, FALSE state with zero current (or voltage) output, and represents the binary value “0,” as does an input write pulse of zero amplitude.

Other variations of the above parameters can be used to configure the spin transistor as a logic gate element. For example, adding an offset of R_(S) to the output is not necessary for operation of logic gates. If the output is synmetrically bipolar, operation as a logic gate could be accomplished by adding a diode to detector 32 such that positive output currents (or voltages) are transmitted and negative currents (voltages) are blocked. If R_(B) and R_(S) are chosen so that the output is offset negative by R_(S), then the output of such a spin transistor can be used for inverted logic. In this way, a negative write pulse would be HIGH, TRUE or “1,” and a zero amplitude write pulse would be LOW, FALSE or “0.” Now, however, the state with M_(C) up M_(E) and M_(C)) is LOW, FALSE or “0,” and the state with M_(C) down (M_(E) and M_(C) antiparallel) is HIGH, TRUE or “1;” the initial relative orientation of M_(E) and M_(C) should be parallel, rather than antiparallel also.

Spin Transistor OR Logic Gate

Operation of specific logical gates is depicted in FIGS. 4–8. In FIG. 4, the application of the present magnetic spin transistor as an OR logic gate is shown.

In FIG. 4( a), a single write line 52 to spin transistor 50 has two input nodes 54 and 56 which can receive two synchronous current pulses as input. The ferromagnetic emitter 62 has more hash marks to signify that its coercivity is larger than the ferromagnetic emitter, and the orientation of its magnetization ME remains always in the initial, up position. The ferromagnetic collector 58 has fewer hash marks to signify that its coercivity is smaller than the coercivity of the ferromagnetic emitter, and the magnetization orientation M_(C) is modifiable and can be set by the field generated by input current pulses.

When performing a logical gate operation, the spin transistor gate 50 undergoes the following three separate steps in time. At time (step) (I) (not depicted in the figure) spin transistor gate 50 is set to an initial condition by a current input pulse on wire 56; for an AND or an OR gate operation, M_(C) is initially set to a down condition [M_(E) and M_(C) antiparallel]; whereas for a NOT, NAND or NOR gate, M_(C) is initially set to an up condition [M_(E) and M_(C) parallel]. The spin transistor gate 50 is now capable of receiving data inputs, which occurs at a next time (step) (ii). Logical data (having binary values of 1 or 0) in the form of input write pulses are received on write wire 56. Depending on the magnitude of these pulses, they may affect (change) the magnetization orientation M_(C) 66 of the ferromagnetic collector 58. At a later time (step) (iii) a bias pulse (i.e. a read pulse) 60 is applied to ferromagnetic emitter 62, and the current (or voltage) at the ferromagnetic collector 58 is sensed by the detector 64. Accordingly, the ferromagnetic collector magnetization may be read out as an output binary “1” or “0” corresponding to some Boolean logical combination of the data input signals.

In the specific embodiment of FIG. 4, the logical operation of a spin transistor as an OR gate is depicted in FIG. 4. In this embodiment, there are two separate data inputs 54 and 56, each of which can have a “1” or “0” input current value, for a total of four possible input write pulse configurations. As mentioned above, the ferromagnetic collector magnetization orientation is initially set to a down, or opposite state to the ferromagnetic emitter.

In FIG. 4( a), a first input combination of two write pulses of zero amplitude (logical data values of “0”) on lines 54 and 56 is shown. The orientation M_(C) of the ferromagnetic collector 66 remains unchanged from its initial condition because no field is generated by wire 56. Consequently, when a read pulse 60 is applied to the logic gate 50, a zero amplitude output 64 (logical “0”) is detected.

In FIG. 4( b), the second and third possible combinations of input states from wires 54 and 56 is shown. Here, a single write pulse of unit amplitude 70 [representing a logical “1” input data value] is applied to either input terminal 54 or 56. The localized field 72, is H=H₁>H_(c,1); when applied to the ferromagnetic collector 58 this field is large enough to re-orient or re-set the magnetization M_(C) 74 of the ferromagnetic collector 58 to an “up” condition so that when a read pulse 76 is applied to the gate 50, a positive output (logical “1”) of unit amplitude 78 is generated.

Finally, in the last possible combination of data input values, shown in FIG. 4( c), two write pulses 80 of a high amplitude [representing logical “1”s] are synchronously applied to the inputs 54 and 56. The field 82 at the ferromagnetic collector is now H=2H₁>H_(c,1); this also causes M_(C) to re-set or re-orient to a different (up) magnetization state 84. Consequently, when a read pulse is applied to the gate 50, a positive output 88 [logical “1”] results.

As can be seen below, the truth table for this magnetic spin transistor logic gate 50 is identical with that of an OR gate.

TABLE 1 Truth Table for Spin Transistor Logic Gate of FIG. 4, an OR gate. Input (line 54) Input Line 56 Output 0 0 0 0 1 1 1 0 1 1 1 1 Spin Transistor AND Logic Gate

In FIG. 5, the application of the present magnetic spin transistor as an AND logic gate is shown. The implementation of an AND gate can be accomplished by one of several ways using a magnetic spin transistor.

In a first configuration, an AND gate can be made by choosing the ferromagnetic collector such that its coercivity H_(c,2) is twice as large as in the previous case, H_(c,2)=2H_(c,1). This can be done by choosing a material with an intrinsically different coercivity or by introducing magnetic anisotropies such as using crystallographic, substrate, or exchange anisotropy.

In a second configuration, the same material with the same coercivity [as the OR gate] H_(c,1) could be used but the inductive coupling parameter [between write wire and ferromagnetic collector] could be weakened, e.g. α=½, so that the field generated at the ferromagnetic collector from a write pulse of amplitude I_(w)=1=H₁/2.

In a third configuration, the same material with the same coercivity as the OR gate could be used, but a smaller current amplitude (half as large as that used previously for the OR gate) could be used. In this configuration, a field large enough to overcome the coercivity H_(C,1) (and thus re-set the magnetization orientation of the ferromagnetic collector to generate a high or “1” output) would only occur when both input write pulses (data values) were of a high amplitude.

The following discussion proceeds for the case where the coercivity has been altered to the value H_(c,2)=2H_(c,1), but an analogous discussion would proceed for the case where the inductive coupling was diminished, or where the current for any particular input was reduced by ½.

The operation of a spin transistor logic AND gate 90 is depicted in FIG. 5. The ferromagnetic emitter 93 is heavily hashed, as in FIG. 4. The hashing of ferromagnetic collector 91 is darker than the ferromagnetic collector 58 of the OR gate depicted in FIG. 4, signifying that the coercivity of the ferromagnetic collector 91 for the AND gate is larger than that of the ferromagnetic collector 58 for the OR gate, H_(c,2)=2H_(c,1).

As with the OR gate embodiment, there are two separate data inputs 92 and 94, each of which can have a “1” or “0” input current value, for a total of four possible input write pulse configurations or combinations. As mentioned above, the ferromagnetic collector magnetization orientation is initially set to a down, or opposite state to the ferromagnetic emitter.

In a first combination shown in FIG. 5( a), at step (ii) note above for the operation of a spin transistor as a logic gate, the input is two write pulses of zero amplitude (representing logic value “0”) applied to write wires 92 and 94. The orientation state M_(C) 96 of the ferromagnetic collector is unchanged from its initial (down) condition, so that (iii) a read pulse 98 applied to the spin transistor logic gate underbar results in zero amplitude (logic value “0”) output 100.

In FIG. 5( b), second and third combinations result when at step (ii) a single write pulse 102 of unit amplitude is applied to either input terminal 92 or 94. Because the coercivity of the ferromagnetic collector is twice as large as before [or because the coupling is half as strong, or because the current at 92/94 is half as much], the field H=H₁<H_(c,2) is not sufficient to reorient the magnetization state M_(C) 104 of the ferromagnetic collector, and (iii) a read pulse 106 applied to the gate 90 results in zero output (logical value “0”) at 108.

In the last combination shown in FIG. 5( c), (ii) two write pulses 110 of a high amplitude [logical “1”] are synchronously applied to the inputs 92 and 94. The field at the ferromagnetic collector is now H=2H₁>H_(c,1), the orientation M_(C) 112 of the ferromagnetic collector reverses (goes from down to up), and (iii) a read pulse 114 applied to the gate 90 results in a positive [logical “1”] output 116.

It can be seen therefore that the output of the spin transistor logic gate 90 is a logic value “1,” only when both data input logic values are “1,” as should be the case for any gate implementing Boolean AND logic. The truth table for this gate appears in Table 2, and is identical with that of an AND gate.

TABLE 2 Truth Table for Spin Transistor Logic Gate of FIG. 5, an AND gate. Input (line 92) Input Line 94 Output 0 0 0 0 1 0 1 0 0 1 1 1 Spin Transistor NOT (Inverter) Logic Gate

In FIG. 6, the application of the present magnetic spin transistor as an NOT (inverter) logic gate is shown. Operating the spin transistor as a NOT gate 120 can be accomplished by making simple modifications to the OR gate configuration, and is depicted in FIG. 6. The ferromagnetic collector is fabricated to have a coercivity H_(c,1), and a write wire 126 with a single input node 128 is fabricated with geometrically reversed polarity so that the positions of input node and ground are interchanged.

In addition, the initialization step (I) for a spin transistor logic gate implementing a NOT logical function [and also the NOR and NAND functions] requires setting the device to a configuration which has the magnetizations of ferromagnetic emitter 124 and ferromagnetic collector 122 parallel.

For this gate embodiment, there is only a single data input line 128, which can have a “1” or “0” input current value, for a total of two possible input write pulse configurations or combinations. As mentioned above, the ferromagnetic collector magnetization orientation is initially set to an up, or identical state to the ferromagnetic emitter.

In a first combination shown in FIG. 6( a), at time (ii) a zero amplitude write pulse (logical value “0”) is transmitted down the write wire 126. The orientation M_(C) 130 of the ferromagnetic collector is not changed and therefore at time (iii), applying a read pulse 132 to the device 120 results in a positive (logical value “1”) output 134.

Similarly, in FIG. 6( b), when a (ii) single write pulse 140 (logical value “1”) generates a field 142 H=−H₀ at the ferromagnetic collector 122 [the field here points down, in the opposite direction as for the OR and AND gates] this causes the magnetization orientation M_(C) 144 of the ferromagnetic collector to reverse, pointing down so that M_(E) and M_(C) are now antiparallel. At time (iii), therefore, a read pulse 146 applied to the gate underbar 120 results in zero amplitude (logical value “0”) output 148. The truth table for the device, presented in Table 3, is identical with that of a NOT gate.

TABLE 3 Truth Table for Spin Transistor Logic Gate of FIG. 6, a NOT gate. Input (line 128) Output 1 0 0 1 Spin Transistor NOR Logic Gate

In FIG. 7, the application of the present magnetic spin transistor as an NOR logic gate is shown. The operation of a NOR gate follows immediately from the description of the OR and NOT gates. The initial state of the device 160 at time (I) is set with the orientations M_(E) and M_(C) of ferromagnetic emitter 162 and ferromagnetic collector 164 parallel (both up). The inputs 166 and 168 and ground 170 of the write wire 172 are fabricated with the same orientation as for the NOT gate, i.e. the polarity is reversed from the sense in FIG. 4, and the coercivity H_(c,1) and coupling efficiency a are chosen to be the same as the OR gate in FIG. 4. Thus, a positive write pulse (input data representing a logical “1”) of amplitude I_(w)=1 is sufficient to generate a local magnetic field that will reverse the ferromagnetic collector magnetization orientation 164 and cause it to point down.

Similar to the OR and AND gate embodiments, there are two separate data inputs 166 and 168, each of which can have a “1” or “0” input current value, for a total of four possible input write pulse configurations or combinations. As mentioned above, the ferromagnetic collector magnetization orientation is initially set to an up, or parallel state to the ferromagnetic emitter.

In a first combination shown in FIG. 7( a), at time (ii) noted above for the operation of a spin transistor as a logic gate, the input is two write pulses of zero amplitude (representing logic value “0”) applied to write wires 166 and 168. The magnetization orientation M_(C) 174 is unchanged, so that at time (iii) a read pulse 176 applied to the gate 160 results in positive (logical value “1”) output of unit amplitude 178.

In the next two possible combinations of inputs shown in FIG. 7( b), at time (ii) a single write pulse of unit amplitude (logical value “1”) 180 is applied to either input terminal 166 or 168. The field 182 |H|=H₁>H_(c,1) is sufficient to reset (reorient) the magnetization M_(C) 184 so that at time (iii) a read pulse 186 applied to the gate 160 results in a zero amplitude (logical value “0”) output 188.

The last combination is shown in FIG. 7( c), where at time (ii) two write pulses 190 (logical value “1”) are synchronously applied to the inputs. The field 192 at the ferromagnetic collector 164 is now |H|=2H₁>H_(c,1), M_(C) reorients to point down 194, and at time (iii) a read pulse 196 applied to the gate underbar 160 results in zero (logical “0”) output 198. The truth table for this gate is presented in Table 4, and is identical with that of a NOR gate.

TABLE 4 Truth Table for Spin Transistor Logic Gate of FIG. 7, a NOR gate. Input (line 166) Input Line (168) Output 0 0 1 0 1 0 1 0 0 1 1 0 Spin Transistor NAND Logic Gate

In FIG. 8, the application of the present magnetic spin transistor as an NAND logic gate 210 is shown. The operation of a NAND gate follows immediately from the description of the other gates above. In FIG. 8 ferromagnetic collector 214 has been marked with fewer hash marks than ferromagnetic emitter 212 and more hash marks than the ferromagnetic collector of the NOR gate 160 to signify that its coercivity [as in the case of the AND gate] is H_(c,2)>H_(c,1), and that its coercivity is less than that of the ferromagnetic emitter 212. In other possible configurations, as discussed above for the AND gate, a weaker coupling, α=½, could be chosen by placing the write wire further away from the ferromagnetic collector, for example. Alternatively reduced current write inputs for the data inputs on lines 230 and 232 could be used.

As with the other gates discussed above, there are two separate data inputs 230 and 232, each of which can have a “1” or “0” input current value, for a total of four possible input write pulse configurations or combinations. In the NAND gate configuration, the ferromagnetic collector magnetization orientation of the spin transistor is initially set to an up, or parallel state to the ferromagnetic emitter.

In a first combination shown in FIG. 8( a), at time (ii) noted above for the operation of a spin transistor as a logic gate, the input is two write pulses of zero amplitude (representing logic value “0”) applied to write vires 230 and 232. The magnetization orientation M_(C) 174 is unchanged, so that at time (iii) a read pulse 218 applied to the gate 210 results in positive (logical value “1”) output of unit amplitude 220.

In the combinations shown in FIG. 8( b), (ii) a single write pulse of unit amplitude 222 (logical data value “1”) is applied to either input terminal. Because the coercivity is twice as large as before, the field 224 |H|=H₁<H_(c,2) is not sufficient to reorient the magnetization orientation M_(C) 226, and consequently at time (iii) a read pulse 228 applied to the gate 210 results in positive (logical data value “1”) output 230.

Finally, in the last combination shown in FIG. 8( c), (ii) two write pulses 232 (representing logic value “1”) are synchronously applied to the inputs. The field 234 at the ferromagnetic collector is now |H|=2H₁>H_(c,2), M_(C) becomes reoriented to a down state 238, and at time (iii) a read pulse 240 applied to the gate 210 results in zero (logical value “0”) output 242. The truth table for this gate is presented in Table 5, and is identical with that of a NAND gate.

TABLE 5 Truth Table for Spin Transistor Logic Gate of FIG. 8, a NAND gate. Input (line 230) Input Line (232) Output 0 0 1 0 1 1 1 0 1 1 1 0 Dynamically Programmable Spin Transistor Logic Gate

While different coercivities were used to implement some of the specific logic gate embodiments described above (the AND and NAND logic gates), it is possible, as explained briefly before, to use a single spin transistor physical structure to implement all of the aforementioned logic gates. In such an approach, the only parameter needed to create a particular type of logic gate is to adjust or program the value of the write current, I_(W) used to input data to the device.

Looking at FIG. 3, for example, when I_(W)=1, the spin transistor operates as an OR gate; if I_(W)=½, the spin transistor operates as an AND gate; if I_(W)=−½, the spin transisto operates as an NAND gate; when I_(W)=−1, the spin transistor operates as a NOT or NOR gate. Thus, the logical function performed by the spin transistor can be varied simply by changing the value of the input current (and thus magnetic field) coupled to the device.

Alternatively, another possibility which may be attractive under certain circumstances is to have a selectable set of write wires so that the coupling to the spin transistor could be varied to configure the device as different logical elements.

The advantage of the above invention is that a single spin transistor not only operates as a logic gate, it can also be dynamically reprogrammed merely using a different input current value to perform a different function as needed or desired by the particular application environment.

Fourth Embodiment—Magnetic Spin Transistor with Gain & Coupling Capability for Creating Spin Transistor Gate Circuits

Whereas high impedance semiconductor gates operate with voltage pulses and multiple gates are linked together electrodynamically, spin transistor gates operate with current pulses. Until the present invention, there has been no mechanism for linking magnetic spin transistors.

The present invention uses inductive coupling to link spin transistors. As seen in FIG. 10, an output line from the ferromagnetic collector of one magnetic spin transistor can generate an output which is used as the input write line of a second gate. Using this mechanism, multiple gates can be linked together to process complex Boolean operations.

In order to inductively couple one spin transistor to another, however, it is necessary that the magnitude of the output current of any transistor be made equal to (or greater than) the amplitude of a write pulse, I_(OUT)>=I_(W); this is the same as demanding that the fanout of a device must be greater than one, i.e. that one device must be capable of setting the state a second device. The present invention, achieves this desired goal of obtaining a current gain, i.e., I_(OUT)>=I_(W).

The magnitude of I_(out) is determined by the transimpedance R_(S) and the parasitic and load resistances R_(B) and R_(L). Since it is also proportional to the bias current it can always be made larger by increasing the amplitude I_(R). However, a significant problem results in prior art spin transistors when I_(OUT) is made to be comparable in magnitude to I_(W): a stray magnetic field from I_(OUT) is large enough alter the magnetization orientation of the ferromagnetic collector. If this occurs, the device becomes unreliable and unstable.

The present invention solves this instability and achieves a fanout larger than 1 by configuring the geometry of the ferromagnetic collector so as to take advantage of certain intrinsic anisotropic properties of ferromagnetic films.

It is well known that thin ferromagnetic films have a large, geometric anisotropy that is typically large enough to confine the magnetization orientation to the plane of the film. In addition, most ferromagnetic films have one or more anisotropy axes in the film plane. An axis along which the anisotropy energy of the film is small is known as an easy magnetization axis, and the two orientations (positive or negative, parallel or antiparallel) along this axis are preferred orientations of the magnetization. Similarly, a direction along which the anisotropy energy is large is a hard magnetization direction and is not a preferred orientation for the magnetization. Quantitatively, the coercivity along an easy axis is smaller than that along a hard axis.

Several factors contribute to the anisotropy energy of a thin ferromagnetic film, including shape anisotropy [i.e. different aspect ratios of thickness to length and width], interactions with the substrate and, for single crystal films, crystallographic orientation. Polycrystalline films deposited with an external field present at the substrate can also have significant anisotropies because the field orients the small evaporant particles so that there is microscopic crystallographic anisotropy. Substrates with, for example, parallel microgrooves can induce significant anisotropies in a ferromagnetic film. Buffer layers can induce similar effects. For example, a film of an antiferromagnetic material can induce a strong anisotropy in an overlaid ferromagnetic film, and the direction and strength of the anisotropy depends on the precise thickness (and stoichiometry) of the antiferromagnetic material.

Using these methods, or combinations of these methods, anisotropies can be induced in any material such that the ratio of the coercivity along the easy axis to that along the hard axis can be of order 10 to 1 (e.g. 100 Oe to 10 Oe). By contrast, a polycrystalline ferromagnetic film patterned as a thin disk on a neutral substrate would have isotropic magnetization in the film plane.

In the discussion that follows, the means for producing the anisotropy is unimportant; and it is assumed that some standard technique known in the art has produced a ferromagnetic collector that is magnetically anisotropic. Ferromagnetic collector geometries which take advantage of this magnetic anisotropy and thus avoid the instability associated with large output currents are schematically depicted in FIG. 9. A ferromagnetic collector electrode 250 lying in the x-z plane is typically a metal bilayer composed of a ferromagnetic film 252 covered by a thin nonmagnetic film 254 which protects the former from oxidation and promotes uniform current flow. As discussed above, there is a large anisotropy energy in the ferromagnetic film in the y direction, and the magnetization in constrained to lie in the x-z plane. In FIG. 9( a), ferromagnetic collector electrode 250 is fabricated with an easy axis along z, and the write wire 256 [or pair of wires] is electrically isolated from the ferromagnetic collector electrode by an insulating layer 264 and is oriented parallel to x so that any field 258 generated by a write pulse at the position of the ferromagnetic collector 252 points along the z axis. This field is used to orient the ferromagnetic collector magnetization M_(C) along the +/− z axis. The ferromagnetic collector is also fabricated with a hard magnetization axis along x, and the output line 260 from the spin transistor is chosen to run along z. The field 262 generated by the output current at the position of the ferromagnetic collector therefore points along the x axis. Since x is a hard magnetization direction, it takes much larger fields, and therefore much larger output currents, to reorient M_(C) in this direction.

Thus, the output current that can be sent through the output wire without causing a reorientation of M_(C) can be much larger than the write current, or in other words, I_(OUT)>>I_(W). In this way the condition necessary for fanout to be greater than one is satisfied, and inductive coupling between two spin transistors can be accomplished.

Any number of collector geometries, only three of which are shown in FIGS. 9( a) to 9(c) are satisfactory for making certain that M_(C) is not re-oriented by a large output current. For example, it is not necessary that the write wire be centered over the ferromagnetic collector as depicted in FIG. 9( b). Applying a coercive field by sending current through a write wire 270 at or near an edge of the ferromagnetic film can be adequate to orient the magnetization of the entire film. Also, the particular choice of easy and hard axis is not important. If the easy axis is along x, the write wire 272 [or pair of wires] can be chosen to be parallel to z and the output line 274 to be parallel to x, as shown in FIG. 9( c). The only general considerations that need to be kept in mind is the fact that the write line should be chosen to be oriented perpendicular to the easy magnetization axis and the output line perpendicular to the hard magnetization axis.

Using this form of inductive coupling, multiple spin transistors, and spin transistor gates can be linked together to perform the processing operations of Boolean algebra. One combination of gates that operates as a half adder is depicted in FIG. 10; as is readily apparent to skilled artisans, any of a number of other combinations can be made, e.g. using NOR and NAND gates. Using the conventions of FIGS. 4–8, the ferromagnetic emitter of each gate has more extensive hash marking to signify a very large coercivity, and to denote that the magnetization M_(E) never changes from up. Spin transistor AND logic gates 300 and 310 have ferromagnetic collectors with medium hash marking, denoting a coercivity larger than that of the ferromagnetic collector of the spin transistor OR logic gate 320 and spin transistor NOT logic gate 330, [or equivalently to denote a weaker coupling α of the write wire] which are hashed lightly.

After initializing the states of the gates, the operation of binary addition can proceed as follows. (1) Write pulses of zero or unit amplitude are simultaneously applied from the two input nodes 302 to the top spin transistor AND logic gate 300 and OR 320 gates. (2) A read pulse is applied to the input 304 of the AND gate 300, with the output of the operation setting the state of the NOT gate 330. (3) Read pulses are simultaneously applied to the inputs 332 and 322 of the NOT 330 and OR 320 gates, and the output of the two gates is input to the write wire 312 of the lower AND gate 310 thus setting its state. (4) The operation is now complete, with the “carry bit” stored in the state of the AND gate 300 and the “total bit” stored in the state of the AND gate 310.

The data is retained in this state, and at any later time the result can be read out by applying read pulses to the inputs 304 and 314 of the two AND gates 300 and 310. A half adder is a fundamental building block of all logical processing operations, and it will be apparent to persons skilled in the art from the present invention that other such building blocks can easily be assembled from magnetic spin transistors of the type described herein. Using half adders, OR, AND, NOT, NOR and NAND gates, all the usual mathematic and processing operations associated with a microprocessor can be performed.

Accordingly it is believed that the present invention provides all the necessary information required to design and construct a typical microprocessor using magnetic spin transistor gates.

Although the present invention has been described in terms of a preferred embodiment, it will be apparent to those skilled in the art that many alterations and modifications may be made to such embodiments without departing from the teachings of the present invention. For example, it is apparent that other types of logical gate elements beyond those illustrated in the foregoing detailed description can be formed using the improved spin transistors of the present invention. Accordingly, it is intended that the all such alterations and modifications be included within the scope and spirit of the invention as defined by the following claims. 

1. A digital processing device comprising: a first magnetoelectronic gate implementing a first logic function and responsive to at least a first type of input signal imposing a first magnetic field to such gate; a second magnetoelectronic gate implementing a second logic function which is coupled to the first magnetoelectronic gate, and which is responsive to at least a second type of input signal imposing a second magnetic field to such gate; wherein said first magnetic field is different from said second magnetic field.
 2. The digital processing device of claim 1, wherein at least said first logic function relates to a memory.
 3. The digital processing device of claim 1, wherein said first logic function and said second logic function relate to different Boolean operations performed on one or more input signals.
 4. The digital processing device of claim 1, including a write line, wherein a first spatial orientation of a first ferromagnetic layer is associated with the first magnetoelectronic gate with respect to such write line and a second spatial orientation of a second ferromagnetic layer is associated with the second magnetoelectronic gate with respect to said write line, such that such first spatial orientation is different from said second spatial orientation.
 5. The digital processing device of claim 1, wherein a first spatial relationship of a write line and a read line associated with the first magnetoelectronic gate is different from a second spatial relationship of said write line and said read line with respect to said said magnetoelectronic gate.
 6. The digital processing device of claim 1, wherein a first coercivity of a first ferromagnetic layer associated with the first magnetoelectronic gate is different from a second coercivity of a second ferromagnetic layer associated with the second magnetoelectronic gate.
 7. The digital processing device of claim 1, wherein at least one of said first logic function and said second logic function can be changed dynamically during operation of the device.
 8. The digital processing device of claim 1, wherein said first magnetoelectronic gate and said second magnetoelectronic gate are incorporated within a microprocessor.
 9. The digital processing device of claim 1 wherein said first magnetoelectronic gate and said second magnetoelectronic gate are spin transistors.
 10. The digital processing device of claim 1 wherein at least said first magnetoelectronic gate includes a low transmission barrier.
 11. The digital processing device of claim 1 wherein an output from said first magnetoelectronic gate drives an input to said second magnetoelectronic gate.
 12. The digital processing device of claim 1 wherein at least a portion of a write current for a write signal is carried by said first magnetoelectronic gate.
 13. A digital processing device comprising: a first magnetoelectronic gate implementing a first logic function; at least one first input line coupled to such first magnetoelectronic gate for imposing a first input magnetic field associated with a first signal to such gate; a second magnetoelectronic gate which is coupled to the first magnetoelectronic gate and which implements a second logic function; at least one second input line coupled to such second magnetoelectronic gate for imposing a second input magnetic field associated with a second signal to such gate; wherein said first input magnetic field and said second input magnetic field are different.
 14. The digital processing device of claim 13, wherein said first signal includes a first amplitude which is different from a second amplitude associated with said second signal.
 15. The digital processing device of claim 13, wherein at least said first magnetoelectronic gate is part of a memory gate.
 16. The digital processing device of claim 13, wherein at least one of said first logic function and said second logic function can be changed dynamically during operation of the device.
 17. The digital processing device of claim 13, wherein at least one of said first logic function and said second logic function can be changed dynamically during operation of the device.
 18. The digital processing device of claim 13 wherein at least said first magnetoelectronic gate includes a low transmission barrier.
 19. The digital processing device of claim 13 wherein at least a portion of a write current for a write signal is carried by said first magnetoelectronic gate.
 20. A digital processing device comprising: at least one first magnetoelectronic gate implementing a first logic function; one or more first input lines coupled to such at least one first magnetoelectronic gate for imposing a first variable input magnetic field associated with a first variable signal to such gate; wherein said first variable signal is adjustable based on a logic operation to be performed by said first logic function, a second magnetoelectronic gate which is coupled to the at least one first magnetoelectronic gate and which implements a second logic function; at least one second input line coupled to such second magnetoelectronic gate for imposing a second input magnetic field associated with a second signal to such gate; wherein said first variable input magnetic field and said second input magnetic field can be different.
 21. The digital processing device of claim 20, wherein said first variable signal is implemented by varying an amplitude of such signal in accordance with a logic operation to be implemented by said first logic function.
 22. The digital processing device of claim 20, wherein said first variable signal is implemented by varying an inductive coupling parameter {dot over (α)} between said one or more first input lines and a ferromagnetic region for said first magnetoelectronic gate in accordance with a logic operation to be implemented by said first logic function.
 23. The digital processing device of claim 20, wherein said first variable signal is implemented by varying a spatial relationship between said one or more first input lines and a ferromagnetic region for said first magnetoelectronic gate in accordance with a logic operation to be implemented by said first logic function.
 24. The digital processing device of claim 20, wherein at least two separate write lines are used for said one or more first input lines.
 25. The digital processing device of claim 20, wherein at least one of said first logic function and said second logic function can be changed dynamically during operation of the device.
 26. The digital processing device of claim 20 wherein at least said first magnetoelectronic gate includes a low transmission barrier.
 27. The digital processing device of claim 20 wherein at least a portion of a write current for a write signal is carried by said first magnetoelectronic gate.
 28. A digital processing device comprising: at least one first magnetoelectronic gate implementing a first logic function; at least one first input line coupled with a first inductive coupling factor {dot over (α)} to such at least one first magnetoelectronic gate; wherein said at least one first input line carries at least one first input signal; a second magnetoelectronic gate which is coupled to the at least one first magnetoelectronic gate and which implements a second logic function; at least one second input line coupled with a second inductive coupling factor {dot over (α)} to such second magnetoelectronic gate wherein said at least one second input line carries at least one second input signal; further wherein said first magnetic coupling factor {dot over (α)} and said second magnetic coupling factor {dot over (α)} are different.
 29. The digital processing device of claim 28, wherein a first distance between said at least one first input line and said at least one first magnetoelectronic gate is different from a second distance between said at least one second input line and said second magnetoelectronic gate.
 30. The digital processing device of claim 29, wherein said first distance and said second distance are associated with different thicknesses of an insulating layer.
 31. The digital processing device of claim 28, wherein said different inductive coupling factors are implemented by a first spatial relationship between said first input line and said first magnetoelectronic gate and a different second spatial relationship between said at least one second input line and said second magnetoelectronic gate.
 32. The digital processing device of claim 28, wherein at least two separate write lines are used for said at least one first input line.
 33. The digital processing device of claim 28 wherein at least a portion of a write current for a write signal is carried by said first magnetoelectronic gate.
 34. A digital processing device comprising: a first magnetoelectronic gate implementing a first logic function; wherein said first magnetoelectronic gate includes a first ferromagnetic region characterized by a first coercivity; at least one first input line coupled to such first magnetoelectronic gate for imposing a first input magnetic field associated with a first signal to such gate; a second magnetoelectronic gate which is coupled to the first magnetoelectronic gate and which implements a second logic function; wherein said second magnetoelectronic gate includes a second ferromagnetic region characterized by a second coercivity; at least one second input line coupled to such second magnetoelectronic gate for imposing a second input magnetic field associated with a second signal to such gate; wherein said first coercivity and said second coercivity are different.
 35. The digital processing device of claim 34, wherein said first coercivity is associated with a first geometry for said first ferromagnetic region and said second coercivity is associated with a second geometry for said second ferromagnetic region.
 36. The digital processing device of claim 34, wherein said first coercivity is associated with a first axis for said first ferromagnetic region and said second coercivity is associated with a second axis for said second ferromagnetic region.
 37. The digital processing device of claim 34, wherein said first coercivity is associated with a first shape anisotropy for said first ferromagnetic region and said second coercivity is associated with a second shape anisotropy for said second ferromagnetic region.
 38. The digital processing device of claim 34, wherein said first coercivity is associated with a first material composition for said first ferromagnetic region and said second coercivity is associated with a second material composition for said second ferromagnetic region.
 39. The digital processing device of claim 34, wherein said first coercivity is associated with a first crystallographic orientation for said first ferromagnetic region and said second coercivity is associated with a second crystallographic orientation for said second ferromagnetic region.
 40. The digital processing device of claim 34, wherein at least one of said first magnetoelectronic gate and said second magnetoelectronic gate have an output current which exceeds an input current.
 41. The digital processing device of claim 34, wherein at least said first magnetoelectronic gate has an output line which is perpendicular to a hard axis of said first ferromagnetic region.
 42. The digital processing device of claim 34, wherein at least said at least one first input line is perpendicular to an easy axis of said first ferromagnetic region.
 43. The digital processing device of claim 34, wherein said at least one first input line overlaps an edge of said first ferromagnetic region.
 44. The digital processing device of claim 34, wherein said an output line overlaps an edge of said first ferromagnetic region.
 45. The digital processing device of claim 34 wherein at least a portion of a write current for a write signal is carried by said first magnetoelectronic gate. 